implementation of the california environmental contaminant … · 2019. 9. 4. · women archived in...
Post on 23-Aug-2020
0 Views
Preview:
TRANSCRIPT
Implementation of the California Environmental Contaminant
Biomonitoring Program: 2014-2015
Fourth Report to the California Legislature
California Department of Public Health
In collaboration with
California Environmental Protection Agency’s
Office of Environmental Health Hazard Assessment and
Department of Toxic Substances Control
GAVIN NEWSOM Governor
State of California
2
Table of Contents
Executive Summary ......................................................................................................................... 3
Introduction .................................................................................................................................... 8
Biomonitoring California Studies .................................................................................................. 12
Measuring Chemical Exposures .................................................................................................... 20
Outreach, Communication, and Public Participation Activities .................................................... 27
Conclusions ................................................................................................................................... 30
Appendix A: Program Structure .................................................................................................... 33
Appendix B: Past Projects and Collaborations .............................................................................. 36
To obtain copies of the report
This report is available online at:
biomonitoring.ca.gov/biomonitoring-california-reports.
Copies may also be requested from the Environmental Health Investigations Branch,
California Department of Public Health, by calling 510-620-3620 or writing to:
Environmental Health Investigations Branch
850 Marina Bay Parkway
Building P-3
Richmond, CA 94804
3
Executive Summary
Biomonitoring—the measurement of chemicals or their metabolites in a person’s body—
provides an overall measure of human exposure to certain chemicals found in air, water, food,
soil, dust, and consumer products. Biomonitoring helps public health officials and researchers
better track the amounts and types of chemicals that get into people from all sources, and
informs decision-makers and the public about potentially toxic chemical exposures that can
affect the health of Californians.
Background The California Environmental Contaminant Biomonitoring Program (the Program) was
established through legislation in 2006 by Senate Bill (SB) 1379 (Perata and Ortiz) and codified
in Health & Safety Code Sections 105440 et seq. Biomonitoring California is a collaborative
effort involving the California Department of Public Health (CDPH) as the lead, the Office of
Environmental Health Hazard Assessment (OEHHA), and the Department of Toxic Substances
Control (DTSC). It receives technical advice and peer review from a Scientific Guidance Panel
(SGP) and input from the public. For more information about Biomonitoring California, visit the
Program website at biomonitoring.ca.gov.
The Program is required to submit progress reports every two years to the Legislature. This
document is the fourth such report. The first three reports can be accessed online.1 This report
highlights Program accomplishments for the time period between January 1, 2014, and
December 31, 2015.
Biomonitoring is an important public health function
Biomonitoring provides the only objective measure of chemical exposures, which may
adversely affect the health of:
The general population
People living in communities impacted by particular industries or pollutants
Vulnerable groups, such as pregnant women, children, or workers
Biomonitoring is a proven scientific tool that can demonstrate whether regulatory and public
health efforts are reducing chemical exposures.
Biomonitoring also offers important information to inform and educate decision-makers and
the public.
1 www.biomonitoring.ca.gov/biomonitoring-california-reports
4
New Biomonitoring California Findings and Other Program
Highlights In establishing Biomonitoring California, the Legislature found that biomonitoring can “provide
data that will help California scientists, researchers, public health personnel, and community
members explore linkages between chemical exposures and health.” Biomonitoring California
has focused to date on building laboratory capabilities, developing techniques to appropriately
communicate results of individual tests to participants (as required by the statute), and
engaging in a series of scientifically based targeted studies of vulnerable subpopulations that
are described in the following sections. Where appropriate, results from the targeted studies
have been compared with data from national surveys, providing valuable information about
exposures in some California subpopulations.
Summary of Studies and Findings
As of December 31, 2015, Biomonitoring California initiated a total of five full project
collaborations and 14 laboratory collaborations. Collectively, these studies include participants
from a wide range of California populations. The studies measure a wide variety of chemicals
with the potential for harming the health of Californians (see Table 1). Two of the five full
project collaborations have been completed (see Appendix B). The following three studies
occurred during the period covered by this report (January 1, 2014, to December 31, 2015):
The Measuring Analytes in Maternal Archived Samples (MAMAS) Study began in April 2014.
MAMAS is a pilot study that measures metals, perfluorinated compounds (PFCs), and persistent
organic pollutants (POPs) in archived maternal serum samples previously collected through the
State’s Genetic Disease Screening Program. This study evaluated the use of archived specimens
to build a statewide sample derived from pregnant women. For more information, please refer
to page 12 of this report.
Key finding from the MAMAS Study:
o Perfluorinated chemicals (PFCs) levels measured in serum samples from pregnant
women archived in 2012 are consistent with levels found in the US population.
The Biomonitoring Exposures Study (BEST) was initiated with a pilot in 2011, and later
expanded to involve more than 450 adult residents of the Central Valley, with oversampling for
Asians and Hispanics. For more information, please see page 12 of this report.
Key findings from the BEST Study:
o There are higher levels of arsenic in people living in the Central Valley compared to
the general US population.
o Over 90% of participants had detectable levels of potentially toxic metals, including
arsenic, cadmium, and mercury in their urine.
5
o Asian/Pacific Islanders generally had higher levels of mercury in their blood
compared to other race and ethnic groups.
o Both Black and Asian/Pacific Islander participants had higher levels of cadmium in
urine, compared to White participants.
The Foam Replacement Environmental Exposure Study (FREES) was launched in June 2015.
FREES is a study designed to measure the effects of replacing or removing foam furniture on
levels of flame retardants in participants’ blood and urine samples. In parallel, collaborators at
UC Davis are measuring changes in levels of these chemicals in participants’ house dust. For
more information, please see page 15 of this report.
Biomonitoring California is continuing to analyze information from these and other studies and
will release additional findings as they become available. Summary results can be accessed at:
biomonitoring.ca.gov/results. Highlights of Program findings to date are available at:
biomonitoring.ca.gov/program-accomplishments.
Laboratory Capacity and Capabilities
Biomonitoring California’s laboratories are collaborating with university researchers and other
expert scientists to analyze samples collected for other studies (i.e., laboratory collaborations).
For example, serum samples from thousands of female educators in the California Teachers
Study (CTS) are being analyzed for persistent organic pollutants, including flame retardants, and
persistent pesticides. The Program’s analyses for CTS led to the key finding that race (non-
white), lower socioeconomic status, and higher body weight were correlated with higher levels
of some flame retardants.
Biomonitoring California has continued to expand its laboratory capability to analyze
environmental chemicals in blood and urine samples and its capacity to detect these chemicals
in larger numbers of people. Since the Program’s inception, Biomonitoring California:
Has developed the capability to measure over 160 distinct chemicals or their breakdown
products in urine, serum, and whole blood.
Obtained specimens from over 7,000 Californians.
Conducted over 18,500 biomonitoring analyses for chemical pollutants, including
metals, flame retardants, phthalates, PFCs, pesticides, bisphenol A, and others.
Communicating Results to Study Participants Biomonitoring California is committed to its mandate to return biomonitoring results to study
participants who request them. Results return materials were developed in coordination with
researchers from the University of California (UC), Berkeley, and reflect best practices for
returning biomonitoring results to participants.
6
To date, the vast majority of participants (96 %) recruited by Biomonitoring California
into full project collaborations have indicated at enrollment that they would like to
receive their results.
Between 2012 and 2015, the Program provided specially designed packets that describe
individual biomonitoring results to over 600 participants. The packets contain test
results, fact sheets, and suggestions on ways to reduce exposures. Each participant has
received multiple results packets, covering different types of analytes.
As part of the BEST study, the Program collected participant feedback on the packets
through surveys and interviews. Participant feedback on the packets has been positive.
In August 2015, Program staff presented a webinar hosted by the Association of Public
Health Laboratories (APHL) detailing Biomonitoring California’s results communication
approach. The webinar was well attended and demonstrated the Program’s leadership
in this area.
A special session on best practices for biomonitoring results return was included on the
November 2015 SGP meeting agenda.
Informing the Public and Supporting Other Programs Biomonitoring California is required by state law to publicly release biomonitoring results, and
has previously developed data summary reports for that purpose. To more effectively and
quickly disseminate our findings, Biomonitoring California launched an online interactive results
database in April 2014 (biomonitoring.ca.gov/results/explore). With this tool, users can view,
print, and download summary biomonitoring results, customized by Biomonitoring California
project, chemical group, or individual chemicals. This online database is an important element
of the Program’s strategy to keep the public informed of Biomonitoring California findings, and
make study results easily accessible to other state, national, and international programs.
Program Priorities Biomonitoring California identified the following priorities and opportunities for maintaining
and improving the Program:
1. Statewide representative sampling
Biomonitoring a representative cross-section of the California population is a key statutory
requirement that would provide important information about levels of environmental chemical
exposures throughout the state, and remains the top priority of the Program.
2. Environmental justice
Conducting biomonitoring in the context of environmental justice is a guiding principle in the
enabling legislation. One of the Program’s top priorities moving forward is to continue to focus
on environmental justice applications of biomonitoring.
7
3. Intervention studies (with an emphasis on consumer products)
Intervention studies provide important information on likely sources of biomonitored
chemicals, by removing or replacing products known to contain the targeted chemicals.
Biomonitoring California considers opportunities to measure chemical exposures from
consumer products before and after an intervention. Information from consumer product
biomonitoring studies can help support the efforts of California’s Safer Consumer Products
program.
4. Chemicals of emerging concern
Biomonitoring California will continue to develop methods to identify new chemicals that pose
potential health risks to Californians by:
Expanding and automating methods to measure chemicals more quickly and accurately.
Pioneering new laboratory methods to broadly screen for and identify new chemicals
emerging as potential concerns for Californians’ health.
5. Program Funding
Biomonitoring California receives baseline state funding of approximately $2.2 million through
five special funds. In addition, from September 2009 through August 2014, the Program
received $2.65 million annually for five years through a cooperative agreement from the
Centers for Disease Control and Prevention (CDC). In September 2014, Biomonitoring California
was awarded a second cooperative agreement from CDC at the maximum allowable amount of
$1.0 million annually for five years. To partially compensate for the reduction in federal funds,
the 2014 Budget Act included state funds of $700,000 per year for two years and four 2-year
limited-term positions (two positions in DTSC and two in CDPH). The 2015 Budget Act included
$550,000 per year for two years and six 2-year limited-term positions for CDPH, and $150,000
and two 2-year limited-term positions for DTSC.
8
Introduction
“Biomonitoring” refers to measuring chemicals in human biological samples, such as blood and
urine. It can provide an overall measure of human exposure to certain chemicals found in air,
water, food, soil, and consumer products. Biomonitoring can help assess the extent of chemical
exposures from all sources, including the environment, consumer products, diet, and
occupation.
Californians experience widespread exposures to a multitude of chemicals, including flame
retardants, pesticides, heavy metals like mercury and arsenic, and substances used in
manufacturing and consumer products (e.g., cosmetics and plastics), many of which pose
health concerns. Recognizing that Californians’ health can be improved by reducing exposures
to harmful chemicals, the Legislature established the California Environmental Contaminant
Biomonitoring Program (also known as Biomonitoring California), which is the first legislatively
mandated, ongoing state biomonitoring program in the country.
Biomonitoring serves an important public health function. It provides a measure of toxic or
potentially toxic chemical exposures that may adversely affect the health of the general
population; people living in communities impacted by particular industries/pollutants; and
vulnerable sub-groups of the population, such as pregnant women and children. Biomonitoring
is a proven scientific tool that can demonstrate whether regulatory and public health efforts are
reducing chemical exposures. Results from biomonitoring studies play a key role in assessing
the efficacy of measures to reduce specific chemical exposures, and in helping to inform efforts
to identify and regulate chemicals of concern.
Biomonitoring California was established by SB 1379 (Perata and Ortiz, Chapter 599, Statutes of
2006). The legislative intent stated that:
“… the establishment of a statewide biomonitoring program will assist in the evaluation of the
presence of toxic chemicals in a representative sample of Californians, establish trends in the
levels of these chemicals in Californians’ bodies over time, and assess effectiveness of public
health efforts and regulatory programs to decrease exposures of Californians to specific
chemical contaminants. A statewide and community-based biomonitoring program will expand
biomedical, epidemiological, and behavioral public health research.”
The primary goal of Biomonitoring California is to monitor, analyze, and report on specific
environmental chemicals detected in blood, urine, and other biological specimens from a
representative statewide sample of Californians. Measuring environmental chemicals in
California residents will help answer such questions as:
9
Which chemicals are in people’s bodies, and how high are the levels?
Are the levels of chemicals increasing or decreasing over time?
Are there groups or subpopulations in California that have higher exposures to specific
toxic chemicals?
Do regulatory efforts, including bans or phase-outs of chemicals, actually reduce
exposures?
Do certain chemicals contribute to the development of chronic diseases or conditions?
Biomonitoring California has built capacity through targeted studies focused on exposures in
vulnerable subpopulations in California. This strategy has allowed the Program to acquire
essential laboratory equipment; train staff; develop methods to measure harmful chemicals,
including emerging contaminants; and successfully pilot methods to communicate results to
participants and the California public. Using this strategy, the Program has successfully
leveraged state resources both by collaborating with other researchers and by acquiring
supplemental extramural support through a cooperative agreement with the CDC. Having
established sufficient capacity, Biomonitoring California is now planning to initiate the
statewide survey (projected for 2018).
Program Priorities and Opportunities Biomonitoring California has established a reputation for developing and using cutting-edge
analytical methodologies and for setting high standards in reporting results to participants and
the public. In order to continue to provide a high-quality state biomonitoring program and meet
the needs of Californians, a series of facilitated planning meetings were convened with
departmental managers and senior staff of Biomonitoring California. Several strategic areas
were identified in order to prepare for the future, such as visioning, decision making,
communication, and methods development.
These findings were shared with all Biomonitoring California staff and key managers in CDPH,
OEHHA, and DTSC; the SGP; the public (via SGP meetings); and other stakeholders. The
following key priorities and opportunities for maintaining and improving the Program were
identified:
1. Statewide representative sampling
Biomonitoring a representative cross-section of the California population will provide important
information about levels of environmental chemical exposures throughout the state, and this
statutory mandate remains the top priority of the Program. The Program has continued to carry
out targeted and community-based studies and analyses of archived samples to develop
capacity for a statewide representative sample (these studies are described below and in
Appendix A). These analyses provide important biomonitoring data that help inform public
10
health practice and policy in California. Targeted studies also add value by highlighting
exposures in high-risk groups, such as: disadvantaged communities with specific exposure
concerns; workers with potential exposures to chemicals not typically monitored in the
workplace; and sensitive populations like pregnant women and infants. Targeted studies also
contribute to the goal of understanding California’s statewide burden of environmental
exposure.
The Program continues to seek collaborations that allow access to samples that may provide a
more representative cross-section of the California population while planning for a statewide
sampling approach (projected for 2018).
2. Environmental justice
Conducting biomonitoring in the context of environmental justice is a guiding principle in the
enabling legislation. One of the Program’s top priorities moving forward is to continue to focus
on environmental justice applications of biomonitoring. Below are two examples of new
Program initiatives, which underscore this focus:
Biomonitoring California is collaborating with the California Environmental Protenction
Agency’s (CalEPA’s) and OEHHA’s California Communities Environmental Health
Screening Tool (CalEnviroScreen) program. CalEnviroScreen is a screening methodology
that can be used to help identify California communities that are disproportionately
burdened by multiple sources of pollution (oehha.ca.gov/calenviroscreen). Data
available through CalEnviroScreen, such as chemical levels in drinking water, can be
used to interpret Biomonitoring California results in areas like the Central Valley.
Biomonitoring California is working with San Francisco community groups to assess
exposure to heavy metals and PFCs among Asian populations. The project will focus on
low-income communities with strong cultural ties to fishing and fish consumption.
3. Intervention studies (with an emphasis on consumer products)
A public health intervention refers to a purposeful action to create, institute, and evaluate
change in the context of improving health. In the case of biomonitoring, an intervention might
include the removal, reduction, or replacement of potentially toxic chemicals or products
containing these chemicals. Biomonitoring California has prioritized interventions focused on
commonly used consumer products, in order to provide specific exposure information that can
help inform the Safer Consumer Product program at DTSC. Below are some examples of
intervention studies that Biomonitoring California has collaborated on:
A study with the UC Davis to assess the changes in biomonitored flame retardant levels
in participants after they remove or replace foam-containing furniture from their homes
(see FREES description).
11
A laboratory collaboration with UC Berkeley to analyze phthalates, triclosan, bisphenol A
(BPA), parabens, benzophenone-3 (BP-3), and creatinine in urine samples from a
population of teenage girls before and after a change to personal care and cosmetic
products (see the Health and Environmental Research in Makeup of Salinas Adolescents
[HERMOSA] study description).
Biomonitoring California will consider additional projects to measure chemical exposures from
consumer products before and after an intervention as opportunities become available for such
studies.
4. Chemicals of emerging concern
Biomonitoring California has prioritized the development of methods to identify new chemicals
that pose potential harm to Californians by:
Expanding and automating methods to quickly and accurately measure additional
chemicals of public health interest.
Pioneering new laboratory methods to broadly screen for and identify new chemicals
emerging as potential concerns for Californians’ health.
The Program continues to conduct activities to measure additional chemicals using its current
methods, and expedite analytical throughput using enhanced automation, where possible. The
Program has begun to explore methodologies for measuring previously unidentified chemicals
that could pose health hazards, including:
Identifying unknown chemicals present in Californians. The Program is developing
methodologies to screen biological samples for previously unidentified chemicals of
potential concern.
Fragrances, such as synthetic musks. Fragrance chemicals are ubiquitous in personal
care products, and exposures are likely to be widespread in Californians. These
chemicals can pose a variety of health concerns. For example, synthetic musks are
biologically active, potentially affecting the body’s natural hormones.
Additional phthalates. The Program is expanding our existing phthalates method to
measure metabolites of additional phthalates that are increasing in use and exposure.
Newer flame retardants. Biomonitoring California continues to track flame retardants
that are replacing PBDEs and/or emerging as high-use chemicals. The Program will work
to develop new methods to measure additional halogenated and organophosphate
flame retardants.
12
5. Program funding
Biomonitoring California receives baseline state funding of approximately $2.2 million through
five special funds. In addition, from September 2009 through August 2014, the Program
received $2.65 million annually for five years through a cooperative agreement from CDC.
When this initial funding cycle came to an end, CDC restructured its funding mechanism for the
second cycle by lowering the award ceiling to allow for additional award recipients.
Biomonitoring California was awarded the maximum allowable amount in this second funding
cycle: $1.0 million annually for five years starting September 2014.
In 2014, the Budget Act included augmented state funds of $700,000 per year for two years and
four 2-year limited-term positions (two positions in DTSC and two in CDPH), and the 2015
Budget Act included $550,000 and six 2-year limited-term positions for CDPH, and $150,000
and two 2-year limited-term positions for DTSC.
Biomonitoring California Long-Term Goals
1. Measure human exposures to chemicals at the state and community level, using
science-based surveys and methods.
2. Examine trends in chemical levels over time.
3. Help assess the effectiveness of:
Environmental regulations
Public and occupational health interventions
Efforts to improve the safety of consumer products
Biomonitoring California Studies
The enabling legislation directs the Program to conduct statewide and community-based
biomonitoring studies contingent on funding (Health and Safety Code [H&SC] section 105441).
To undertake such studies, Biomonitoring California has engaged in collaborations with other
researchers and has obtained archived biological samples collected by other public health
programs across California.
The Program’s studies thus far include varied sets of California residents and workers with a
focus on subpopulations that may be especially vulnerable or that may have greater chemical
exposures, including pregnant women and residents of agricultural communities.
Results from Biomonitoring California studies are compared to national data collected by the
CDC to determine whether the levels of contaminants in the California groups are higher, lower,
or the same as in the nationwide population. In some cases, collaborating researchers are also
13
planning to follow study participants over time to assess potential associations between
biomonitoring results and health outcomes. The Program’s ongoing studies and collaborations
are laying the groundwork for better characterizing chemical exposures in California’s diverse
population, including racial and ethnic groups underrepresented in national biomonitoring
studies.
The Program has carried out two types of biomonitoring studies:
Full project collaboration: These are studies designed by Biomonitoring California staff,
often in collaboration with other researchers. Biomonitoring California is responsible in
whole or in part for:
1. Study design, sample collection, and collection of exposure data;
2. Laboratory analyses of blood, urine, and/or serum samples;
3. Returning detailed information on biomonitoring results to all participants who
request to receive their results.
Laboratory collaboration: These are studies designed by external researchers, with
Biomonitoring California providing laboratory support. Biomonitoring California is
responsible for laboratory analyses and may provide additional consultation upon
request.
In the time since the third report to the Legislature (covering the period January 2013 through
December 2014), the number of participants in Biomonitoring California projects has continued
to increase. All full project collaborations and some lab collaborations were supported in part
by CDC cooperative agreements 5U38EH000481 and 5U88EH001148. Collaborations with
external partners allow the Program to leverage existing resources.
Full Project Collaborations Three full project collaborations and the MAMAS statewide pilot study, which were conducted
during 2014-2015, are discussed below. Results of these studies are posted in the Program’s
interactive database, biomonitoring.ca.gov/results, as they become available.
1. Measuring Analytes in Maternal Archived Samples (MAMAS)
The MAMAS pilot study analyzes maternal serum samples collected through CDPH’s Genetic
Disease Screening Program (GDSP). The MAMAS study has the potential to provide an excellent
approximation of a statewide sample of pregnant women. Participation in the prenatal
screening program is high (approximately 70% of pregnant women). Samples were selected to
equally represent White, Black, Hispanic, and Asian mothers from across the state.
The MAMAS study differs from other full collaborations in two ways:
14
1. The study uses samples collected in the past by the CDPH GDSP, which obtains the
samples through routine prenatal screening. Biomonitoring California identifies a subset
of these samples to analyze for levels of specific chemicals (more detail below).
2. Samples are not associated with any personal identifiers, such as name and address. The
Program cannot, therefore, return results to participants.
The first phase of the pilot study, MAMAS-1, analyzed 460 samples obtained from GDSP
archives. Samples represented mothers from San Diego and Orange County who had
undergone prenatal screening in 2012. Samples were analyzed for metals, perfluorinated
chemicals (PFCs), and POPs, which include polybrominated diphenyl ethers (PBDEs),
polychlorinated biphenyls (PCBs), and organochlorine pesticides (OCPs). MAMAS-1 found PFC
levels were consistent with levels found in the overall US population. Data from this phase also
indicated that the serum separator gel used by GDSP was contaminated with several metals.
Because this makes quantifying metals in MAMAS samples infeasible, the decision was made to
drop metals as an analytical panel and measure only PFCs and POPs (listed above).
A subsequent phase of the pilot study, MAMAS-2, extended sampling statewide to provide data
on maternal exposures throughout California. By the end of 2015, 540 new samples were
received from four geographic regions (Alameda and Contra Costa counties, San Bernardino
and Riverside counties, Los Angeles County, and Northern California counties) representing
mothers who had undergone prenatal screening in 2015. MAMAS-2 samples will be analyzed
for POPs and PFCs.
The MAMAS pilot demonstrated the feasibility of using archived serum samples from GDSP for
some biomonitoring analyses, but several limitations were identified:
No exposure information and limited demographic information are available. Therefore,
analysis of MAMAS samples can only indicate the level of chemical exposure in the
population, and cannot identify potential sources.
Each sample contains a very small volume of serum, which limits the number of
analyses.
Of the fourteen classes of chemicals listed in Table 1, only four (PFCs, PBDEs, PCBs, and
OCPs) can be measured in serum samples from GDSP. The collection tubes used by
GDSP are contaminated with metals, which prevents accurate analyses of metals in
these serum samples. GDSP collection protocols are outside the control of
Biomonitoring California.
Despite these challenges, the MAMAS study provides useful information on some chemicals
across the state. Archived samples can be acquired quickly and easily, and are relatively
inexpensive when compared to costs associated with sample collection in other biomonitoring
15
exposure studies. MAMAS samples can be used to assess emerging chemicals of concern and to
monitor trends in chemicals over time.
2. Biomonitoring Exposures Study (BEST)
Biomonitoring California is collaborating with the Kaiser Permanente Division of Research,
Research Program on Genes, Environment and Health to conduct the two-phase project known
as the BEST. Kaiser Permanente membership in California’s Central Valley is demographically
similar to the entire population of northern California with respect to characteristics such as
educational attainment and race/ethnicity, which are known to be important determinants of
long-term health outcomes.
In Phase 1, or “Pilot BEST,” Biomonitoring California measured environmental chemical
exposures in 112 adult Kaiser Permanente members living in the Central Valley. Recruitment
was based on achieving balanced distributions across characteristics of race/ethnicity, gender,
and age. Pilot BEST laboratory analyses were completed in 2013, and all results were returned
to participants in 2014. Summary data are posted on the Program website.
Pilot BEST participants were sent results return evaluation surveys, and about 40% completed
them. Analyses show that 96% of the respondents were glad to have participated in Pilot BEST
and were satisfied with the information they received.
In Phase 2, known as “Expanded BEST,” environmental chemical exposures are being measured
in an additional 341 adult Kaiser Permanente members in the Central Valley. Expanded BEST
focused on recruiting Hispanics and Asian/Pacific Islanders and included provisions to enable
participation by those who speak only Spanish. Questionnaires (in English and Spanish), medical
information, and blood and urine samples have been collected;2 analyses began in 2014.
Analyses are being conducted on laboratory results and questionnaire data from the two
phases of BEST to better characterize potential exposure pathways for selected chemicals. The
Program is examining results by demographic characteristics in order to better describe any
differences among sub-populations. In-depth analyses are underway for metals, PFCs, and
PBDEs in conjunction with exposure data from participant questionnaires. Additionally,
Biomonitoring California is using CalEnviroScreen3 data on water contamination to investigate
the potential contribution of arsenic in residential drinking water to arsenic exposure in BEST
participants.
2 Of the samples collected from 341 individual participants, 337 serum samples, 315 blood samples, and 274 urine samples could be analyzed. 3 California Communities Environmental Health Screening Tool
16
The status of BEST sample collection and data analyses as of the reporting period is summarized
below:
Exposure questionnaire data and biological samples were collected from 453 adult Kaiser
Permanente members.
Laboratory analyses for 119 chemicals or their metabolites were completed for Expanded
BEST in the current reporting period, and result packets have been returned to participants
for all these analyses.
Participants in Expanded BEST who had elevated inorganic arsenic levels were offered
retesting and a follow-up questionnaire to help identify additional potential sources of
exposure.
Data analyses comparing BEST results to national levels have been completed.
Summary results for Pilot and Expanded BEST are posted on the Program’s website.
Preliminary findings from BEST include:
Higher levels of arsenic were found in both the Pilot and Expanded BEST populations
compared to the general US population.
Metals with known serious health concerns, including arsenic, cadmium, mercury, and lead,
were detected in all participants.
Women in Expanded BEST had higher blood levels of cadmium compared to men, but lower
levels of lead.
Asian/Pacific Islanders in Expanded BEST generally had higher levels of mercury in their
blood compared to other race/ethnic groups.
Both Black and Asian/Pacific Islander participants had higher levels of cadmium in urine,
compared to White participants.
Factors potentially contributing to these differences, including lifestyle, diet, and country of
birth, are being investigated. For more information on Pilot and Expanded BEST, visit:
biomonitoring.ca.gov/projects/biomonitoring-exposures-study-best-1pilot and
biomonitoring.ca.gov/projects/biomonitoring-exposures-study-best-2expanded.
3. Foam Replacement Environmental Exposure Study (FREES)
Biomonitoring California is collaborating with UC Davis on a study to assess the changes in
flame retardant levels in serum (PBDEs) and urine (OPFRs) samples from participants after they
remove or replace foam-containing household furnishings. Launched in June 2015, this small-
scale intervention study will provide data on the levels of a wide range of flame retardants
present in homes and household residents. Twenty-eight participants were recruited through
December 2015.
17
As of December 31, 2015, FREES has:
Recruited approximately 28 participants to the study and conducted initial exposure
assessment.
Started collection of exposure questionnaire data and samples from homes and
household residents.
Laboratory Collaborations The seven laboratory collaborations conducted during 2014-2015 are discussed below. As
results become available, they are posted on the Program’s website,
biomonitoring.ca.gov/results. Descriptions of additional laboratory collaborations are included
in Appendix B: Past Projects and Collaborations.
1. Health and Environmental Research in Makeup of Salinas Adolescents
(HERMOSA) Study
The HERMOSA (“beautiful” in Spanish) Study is designed to investigate chemical exposures
from personal care and cosmetic products in a small group of teenage girls. Biomonitoring
California laboratories analyzed levels of phthalates, triclosan, BPA, parabens, BP-3, and
creatinine in urine samples from participants. HERMOSA investigators chose these chemicals
based on their potential to adversely affect the endocrine (hormonal) system. The study
included an intervention in which participants were provided alternative personal care products
not containing the chemicals tested for to determine whether this would reduce levels of these
chemicals in their bodies.
The HERMOSA Study was conducted as a joint effort of researchers at the UC Berkeley; La
Clinica de Salud del Valle de Salinas; and a team of youth researchers from the CHAMACOS
(Center for the Health Assessment of Mothers and Children of Salinas) Youth Community
Council. Funding for the study was provided by the California Breast Cancer Research Program.
Key findings include:
Over 90% of the HERMOSA participants had detectable levels of triclosan, BP-3, methyl
paraben, propyl paraben, and phthalates in their urine.
Levels of phthalates, parabens, and BP-3 found in the HERMOSA study participants were
slightly higher than levels found in the national population.4
Girls who wore makeup more frequently were found to have higher paraben levels.
4 National levels were determined based on a comparable population of participants ages 14-18 from the 2011-2012 National Health and Nutrition Examination Survey (NHANES)
18
The intervention (i.e., switching to alternative products for three days) substantially
reduced urinary concentrations of some of the study chemicals. These reductions in
chemical concentrations included monoethyl phthalate (27% reduction), BP-3 (36%
reduction), methyl paraben (44% reduction), propyl paraben (45% reduction), and
triclosan (36% reduction).
2. Pregnancy Environment and Lifestyle Study (PETALS)
Biomonitoring California laboratories measured BPA, triclosan, and BP-3 levels in urine samples
from 300 pregnant women diagnosed with gestational diabetes mellitus (GDM) and 600
pregnant women who did not have GDM (controls). These chemicals may interfere with the
body’s natural hormones. PETALS aims to identify the contribution of the measured chemicals
to the risk of GDM in expectant mothers. Two urine specimens from each of these 900 study
subjects were analyzed for these chemicals, for a total of approximately 1,800 analyses. As of
December 2015, the Program’s laboratories had analyzed and reported 228 results.
3. Los Angeles Taxi Driver Study
This UC Los Angeles (UCLA) Environmental Health Sciences study is designed to measure
polycyclic aromatic hydrocarbon (PAH) exposures in non-smoking taxi drivers from the Greater
Los Angeles Area. PAHs are a known component of motor vehicle exhaust and may contribute
to respiratory problems, affect the developing fetus and the body’s natural hormones, and
increase cancer risk. Taxi drivers were studied because of their frequent occupational exposure
to PAHs. Biomonitoring California measured levels of PAHs in 232 samples from 22 taxi drivers
collected before and after work shifts and from four individuals with low exposure to traffic.
The study found that median concentrations of 1-hydroxypyrene, a commonly used marker for
total PAH exposure, were 125% higher than the US general population, and 50% higher than a
group of UCLA students. UCLA conducted the data analysis. Results will be used to help
evaluate the effectiveness of exposure mitigation strategies.
4. California Teachers Study
The California Teachers Study (CTS) is a large, multi-institutional, statewide cohort study
conducted by the Cancer Prevention Institute of California, the City of Hope, the University of
Southern California, and UC Irvine to study factors influencing women’s health among active
and retired female school teachers and administrators in California. In a sub-study focusing on
links between chemical exposures and breast cancer, Biomonitoring California laboratories are
analyzing levels of PFCs, PBDEs, and other POPs (PCBs and OCPs) in serum samples from
women with breast cancer compared to women without breast cancer. Recruitment was
completed in 2014. For more information about this study, visit
biomonitoring.ca.gov/projects/california-teachers-study-cts. As of December 2015:
19
Approximately 2,500 samples were transferred to Biomonitoring California laboratories,
of which more than half have been analyzed for PFCs and one-fourth have been
analyzed for other POPs (PCBs, PBDEs, and OCPs).
The Program has posted results for a subset of CTS participants in our interactive
database (biomonitoring.ca.gov/results). More results will be added as they become
available.
Key findings include:
As part of CTS, investigators examined predictors of flame retardant exposures. Certain
characteristics were correlated with higher exposures for some flame retardants. Non-
white, lower socioeconomic status, and heavier weight individuals were likely to have
higher levels of flame retardants.
Living close to solid waste disposal sites may be related to higher serum PBDE levels,
including BDE-47 and BDE-100.
5. California Childhood Leukemia Study (CCLS)
The CCLS is a case-control study at UC Berkeley with over 3,000 enrolled families. In a small sub-
study, Biomonitoring California analyzed 48 blood samples collected in 2006-2007 from
mothers living in households with high levels of flame retardants (PBDEs) in dust. This effort
was first reported on in the Third Report to the Legislature. The purpose of the collaboration is
to examine a possible link between flame retardant exposure in the environment and childhood
leukemia. Data are available on the Program website: biomonitoring.ca.gov/projects/california-
childhood-leukemia-study-ccls.
6. Community Health Impacts from Mining Exposures Study (CHIMES)
CHIMES is a collaboration between the Sierra Streams Institute and the Cancer Prevention
Institute of California. The study is an investigation into the human health consequences of
residence in a mining-impacted community, and was designed with significant community
involvement. A total of 60 women over the age of 21 who are residents of western Nevada
County were recruited. Biomonitoring California provided laboratory and program support,
including conducting analyses of levels of metals, including arsenic and cadmium; providing
input on the results return approach and protocols for evaluating elevated levels of metals; and
offering other consultation as needed. Partners in this collaboration analyzed biomonitoring
results with questionnaire data to explore potential exposures to waste metals from mining.
Statistical analyses are ongoing, and results will be released as they become available.
7. Combined Antioxidant and Preeclampsia Prediction Studies (CAPPS)
Biomonitoring California laboratories partnered with Stanford University to measure metals in
archived serum samples from the National Institute of Child Health and Human Development
20
Maternal Fetal Medicine Unites Network specimen bank as part of CAPPS. Biomonitoring
California analyzed samples from 75 preterm birth cases and 75 term births. Findings indicated
that higher serum levels of heavy metals were not associated with spontaneous preterm birth.
Measuring Chemical Exposures
Biomonitoring California’s two state laboratories are nationally recognized for their leadership
and expertise in biomonitoring analytical methods. Each lab has unique areas of expertise to
maximize analytical capabilities across the program.
The Environmental Health Laboratory (EHL), a branch of CDPH, has primary responsibility within
Biomonitoring California for developing analytical methods and measuring metals in blood,
serum, and urine, and non-persistent organic chemicals, such as phthalates, phenols, and some
pesticides, in urine. EHL also oversees sample management and laboratory quality assurance
for the Program.
The Environmental Chemistry Laboratory (ECL), a division of the DTSC, focuses on developing
methods for and measuring persistent organic chemicals, such as flame retardants, PCBs, PFCs,
and OCPs in serum, that bioaccumulate in people. ECL leads the Program’s effort to broadly
screen for and identify new chemicals emerging as potential concerns for Californians’ health.
As of December 2015, the Program can measure 161 chemicals in 14 chemical groups, which
include metals, pesticides, flame retardants, chemicals from personal care products and
plastics, and other persistent pollutants such as PCBs. Chemicals that Biomonitoring California
labs can measure are listed in Table 1. In 2015, Biomonitoring California added new analytical
methods to measure OPFRs, which are replacement flame retardants for banned PBDEs in
polyurethane foam and other materials; and chemicals that are structurally similar to BPA.
Figure 1 shows the rapid expansion of laboratory capability since the beginning of the Program
in 2007 to 2013. In the First Report to the Legislature (2007-2009), laboratory capability
included measurement of just three metals in blood and one pesticide in urine. By the Second
Report (2010-2011), Biomonitoring California laboratories had the capability to measure more
than 60 chemicals or their breakdown products in blood, urine, and serum. At the close of
2015, the Program was able to analyze 161 chemicals.
21
Figure 1 Corresponding Table for Screen Readers: Number of Chemicals Analyzed by Year
Year Number of Chemicals Analyzed 2007 Capable of measuring 3 chemicals 2008 Capable of measuring 3 chemicals 2009 Capable of measuring 4 chemicals
2010 Capable of measuring 9 chemicals 2011 Capable of measuring 64 chemicals 2012 Capable of measuring 117 chemicals 2013 Capable of measuring 137 chemicals 2014 Capable of measuring 153 chemicals 2015 Capable of measuring 161 chemicals
22
Table 1. Chemicals that Biomonitoring California Labs Can Measure
Chemical group Description of chemicals in the lab panel
Organophosphate flame retardants
New Method: Added 2015 Because of the historically high levels of flame retardants in Californians, the Program has made it a priority to measure banned flame retardants (i.e., PBDEs) and their substitutes to evaluate the effectiveness of new policies and interventions. As brominated flame retardants are phased out, phosphate-based flame retardants have been entering the market in larger quantities. In 2015, Biomonitoring California initiated measuring organophosphate flame retardants in urine. Bisphenol-A
analogs and substitutes
New Method: Added 2015 BPA is being voluntarily phased out of a number of consumer products because of its potential effects on the endocrine system and action of hormones. However, chemicals with similar structures, such as bisphenol S (BPS), are still used in products and show similar biological activity as BPA, including potential hormonal effects. Biomonitoring California developed a new method to measure selected BPA analogs, some of which are BPA substitutes, in urine.
Environmental phenols
Environmental phenols have a wide variety of uses, such as in personal care and other consumer products. These chemicals share a common chemical structure. Some examples of environmental phenols are BPA, triclosan, BP-3, and parabens. This group of chemicals may interfere with the body’s natural hormones. Biomonitoring California measures environmental phenols in urine.
Polybrominated diphenyl ethers and their metabolites (PBDEs and OH-BDEs)
PBDE flame retardants were commonly added to polyurethane foam used in upholstered furniture and in some infant products. PBDEs were also used in electronics and insulation for cables and wires. US production of penta- and octa-PBDEs ended by 2006. PBDEs have spread through the environment and break down slowly. Scientists have measured the world’s highest levels of PBDEs in California residents. PBDEs may interfere with the body’s natural hormones, may harm the developing fetus, and may decrease fertility. Biomonitoring California measures PBDEs and hydroxy-PBDEs in serum.
23
Chemical group Description of chemicals in the lab panel
Metals Metals are used in many industries and found in a variety of products. Biomonitoring California measures arsenic (total and specific forms), cadmium, cobalt, lead, manganese, mercury, molybdenum, thallium, tungsten, and uranium.
Some forms of arsenic (“inorganic arsenic”) may harm the developing fetus and contribute to cardiovascular disease, and can increase cancer risk, while other forms found in seafood are not considered to be a health concern.
Cadmium, lead, and mercury are toxic metals with established levels of concern that can cause a range of health effects, including cancer and toxicity to the developing infant and child.
Cobalt is essential as part of vitamin B12, but in other forms can increase cancer risk and harm the heart, thyroid, and nervous system.
Manganese and molybdenum are essential nutrients that can be toxic at higher exposure levels.
Thallium is a highly toxic metal that can harm many vital processes in the body. The health effects of tungsten are not well known, and its potential to affect the immune system or contribute to cancer risk is currently being studied.
Natural uranium is a weakly radioactive metal that can cause kidney damage and increase cancer risk.
Biomonitoring California measures metals in urine and/or blood (whole blood, plasma and serum).
Perfluorinated chemicals (PFCs)
PFCs are used to make various products resistant to oil, stains, grease, and water. Some example products that use PFCs include non-stick cookware, stain-repellent carpets and clothing, and grease-repellent food containers. There is concern that PFCs may affect the developing fetus and child, decrease fertility, interfere with the body’s natural hormones and the immune system, and increase cancer risk. Biomonitoring California measures PFCs in serum. The broader category of “perfluoroalkyl and polyfluoroalkyl substances (PFASs),” which includes PFCs, was added to the list of designated chemicals in 2015, and the Program is working to expand laboratory methods on this class of chemicals.
24
Chemical group Description of chemicals in the lab panel
Organochlorine pesticides (OCPs)
The OCPs measured by Biomonitoring California are no longer used in the United States. Because OCPs last a long time in the environment, they can still be found in high-fat fish, meat, and dairy products. Examples of OCPs include Dichlorodiphenyltrichloroethane (DDT), which is still used in some other countries, and chlordane. OCPs may affect the developing fetus and interfere with the body’s natural hormones, and may increase cancer risk. Biomonitoring California measures OCPs in serum.
Organophosphate (OP) pesticides
OP pesticides are used in commercial agriculture to control pests on fruit and vegetable crops. OP pesticides are also used in home gardens, for flea control on pets, and in some no-pest strips. OP pesticides may affect the nervous system and may harm the developing fetus, possibly affecting later learning and behavior. Biomonitoring California measures OP pesticide metabolites in urine.
Pyrethroid pesticides
Pyrethroid pesticides are common ingredients in pest control products for the home and garden. They are also used to control insects on commercial agricultural crops and livestock. Some pyrethroid pesticides may affect the developing fetus and interfere with the body’s natural hormones, and may increase cancer risk. Biomonitoring California measures pyrethroid pesticide metabolites in urine.
Herbicides Herbicides measured by Biomonitoring California include 2,4-D and 2,4,5-T. 2,4-D is found in some home lawn products designed to kill weeds. There is concern that 2,4-D may interfere with the body’s natural hormones and affect the developing fetus, and may increase cancer risk. 2,4,5-T was used in the past to control weeds but is no longer used due to toxicity concerns. Biomonitoring California measures these herbicides in urine.
Polychlorinated biphenyls (PCBs)
PCBs were widely used to insulate electrical equipment and as plasticizers. PCBs were banned in the late 1970s but are still in some old equipment and products. They have spread through the environment and take a long time to break down. They are found in some high-fat fish and high-fat animal products, and also in old caulk and old fluorescent light fixtures. Exposure to PCBs can affect the developing fetus and interfere with the body’s natural hormones, and may increase cancer risk. Biomonitoring California measures PCBs in serum.
25
Chemical group Description of chemicals in the lab panel
Phthalates Phthalates are added to vinyl to make it soft and flexible. Vinyl products include shower curtains, flooring, and plastic tubing. Phthalates are also used in scented products, coatings like nail polish and paint, and a variety of other consumer products. Phthalates can interfere with the body’s natural hormones and affect development and fertility, and some phthalates may increase cancer risk. The male reproductive system is especially sensitive to phthalate exposure during development. Biomonitoring California measures phthalate metabolites in urine.
Perchlorate Perchlorate is an ingredient in rocket fuel and explosives. It also occurs naturally in dry regions, such as in the Southwestern United States. Industrial uses of perchlorate have led to contamination of soil, groundwater, and drinking water in some areas of California. Perchlorate lasts a long time in the environment and can accumulate in various crops. Perchlorate can interfere with the thyroid gland’s ability to use iodide, which can decrease the production of thyroid hormones. Perchlorate may affect the developing fetus and child and may increase risk factors for heart disease. Biomonitoring California measures perchlorate in urine.
Polycyclic aromatic hydrocarbons (PAHs)
PAHs occur naturally in petroleum products, such as gasoline and diesel, and are formed when these products are burned. PAHs are found in tobacco and wood smoke. They also form when foods are grilled, barbecued, or roasted. PAHs may contribute to respiratory problems, affect the developing fetus and the body’s natural hormones, and may increase cancer risk. Biomonitoring California measures PAH metabolites in urine.
When the First Report to the Legislature was prepared, the Program had only begun to analyze
specimens as part of the process of validating newly developed methods. As reported in the
Second Report to the Legislature, the Program had rapidly expanded to conduct more than
1,500 analyses during 2010-2011 (Figure 2). The Program’s analytical capacity5 saw
unprecedented growth from 2012-2014 but then trended downward in 2015 when the first
CDC cooperative agreement ended.
During the two-year period covered by this report (2014-2015), Biomonitoring California
conducted more than 10,000 biomonitoring analyses for potentially toxic chemicals or their
breakdown products, including heavy metals, flame retardants, phthalates, and pesticides.
5 Analytical capacity refers to the number of specimens the lab can analyze during a given time period. A single blood or urine sample may yield several specimens for analysis for different chemical classes
26
Overall, the larger relative number of analyses over these two years are due to the use of
archived samples and limiting the analyses to only two panels (metals and PFCs), which allows
for a faster turnaround time.
Figure 2 Corresponding Table for Screen Readers: Analytical Capacity by Year Year Analytical Capacity 2009 50 specimens per year
2010 528 specimens per year 2011 1024 specimens per year 2012 2556 specimens per year 2013 3677 specimens per year 2014 6246 specimens per year 2015 4515 specimens per year
27
Outreach, Communication, and Public Participation
Activities
H&SC Section 105451 directs Biomonitoring California to “provide opportunities for public
participation and community capacity building” to allow for “meaningful stakeholder input” and
to “develop a strategy and plan … to establish the framework for integrating public
participation in this program.” Opportunities for public involvement and the Program’s Public
Involvement Plan, which provides an overview of the range of public involvement efforts being
carried out by Biomonitoring California, can be found online at biomonitoring.ca.gov/public-
involvement.
Communicating Biomonitoring Results A distinctive feature of the Program is the statutory requirement to return biomonitoring
results to study participants who request them (H&SC Section 105443), even if the health
implications of these results are scientifically uncertain. This poses a challenge for the Program
to interpret biomonitoring results and convey their potential health implications to individuals,
particularly when a particular chemical’s toxicity in humans has not been well studied.
To meet the results communication challenge, the Program has developed a standard template
to return results to participants,6 offered in both English and Spanish. The template includes a
cover letter, a project description page, individual results for chemical levels with comparison
values and a text explanation, and chemical-specific fact sheets. The chemical-specific fact
sheets, available online at biomonitoring.ca.gov/chemicals/fact-sheets, briefly summarize the
sources of chemicals in the environment, possible health concerns, and possible ways to reduce
exposure. Between 2012 and 2015, the Program provided results packets to the more than 600
participants who requested them. As part of the BEST study, the Program collected participant
feedback on the packets through survey and interviews. Participant feedback on the packets
has been positive.
In August 2015, Program staff gave a webinar hosted by the Association of Public Health
Laboratories (APHL), detailing Biomonitoring California’s results communication approach. A
special session on best practices for biomonitoring results return was held at the November
2015 SGP meeting (biomonitoring.ca.gov/events/biomonitoring-california-scientific-guidance-
panel-meeting-november-2015).
6 biomonitoring.ca.gov/sites/default/files/downloads/Cover%20letter%20and%20Mock%20EBEST%20packet.pdf
28
Further details on the Program’s efforts to effectively communicate biomonitoring results can
be found in a new section of the website, available at:
biomonitoring.ca.gov/results/communicating-results.
Program Website The Program continues to expand and improve the website (biomonitoring.ca.gov) as an
important tool for public outreach. In April 2014, the Program launched an interactive results
database that includes summary biomonitoring results from Biomonitoring California projects.
The database is available online at biomonitoring.ca.gov/results/explore. Users can customize
the display of the results from the database by choosing projects, chemical groups, or individual
chemicals. The customized results can easily be printed or exported as a Microsoft Excel file. A
glossary was added to define the terms used in the results database and elsewhere on the
website. During 2015, the Program expanded the Spanish content on the website, with new
translations of project pages, chemical pages, and chemical-specific fact sheets.
Other ongoing public involvement activities include maintenance of a listserv with 1076 active
subscribers as of December 2015. Notes are sent to subscribers approximately twice per month
informing them of Program activities and new materials posted on the website, such as
biomonitoring results. In 2015, the format for listserv notes was modified to optimize viewing
on mobile devices.
Publications The following scientific articles were published in 2014-2015. For more information, visit
biomonitoring.ca.gov/biomonitoring-california-publications.
Brown FR, Whitehead TP, Park J-S, Metayer C, and Petreas MX. Levels of non-
polybrominated diphenyl ether brominated flame retardants in residential house dust
samples and fire station dust samples in California. Environmental Research 2014; 135,
9–14.
Dobraca D, Israel L, McNeel S, Voss R, Wang M, Gajek R, Park J-S, Harwani S, Barley F,
She J, Das R. Biomonitoring in California firefighters: Metals and perfluorinated
chemicals. J Occup Environ Med. Jan 2015; 57(1): 88–97.
Fan R-F, Wang D-L, She J. Method development for the simultaneous analysis of trans,
trans-muconic acid, 1, 2-dihydroxybenzene, S-phenylmercapturic acid and S-
benzylmercapturic acid in human urine by liquid chromatography/tandem mass
spectrometry. Analytical Methods 2015; 7, 573 – 580.
Gavin QW, Ramage RT, Waldman JM, She J (2014). Development of HPLC-MS/MS
method for the simultaneous determination of environmental phenols in human urine.
29
Intern J Environ Anal Chem 94(2):168-182 doi: 10.1080/03067319.2013.814123 Epub:
09 Jul 2013.
Guo W, Nelson D, Hurley S, Reynolds P, Guo T, Wang M, Park J-S, Petreas M. Pilot study
to assess effects of collection tube types and processing delay on measurements of
persistent organic pollutants and lipids in human serum. Chemosphere 2014; 116:75-82.
Park J-S, Voss RW, McNeel S, Wu N, Guo T, Wang Y, Israel L, Das R, Petreas M. High
exposure of California firefighters to polybrominated diphenyl ethers. Environ. Sci.
Technol., 2015 Mar 3; 49(5):2948-58. doi: 10.1021/es5055918. Epub 2015 Feb 18.
Petropoulou SSE, Duong W, Petreas M, Park J-S. 2014. Fast liquid chromatographic-mass
spectrometric method using mix-mode phase chromatography and solid phase
extraction for the determination of 12 mono-hydroxylated brominated diphenyl ethers
in human serum. Journal of Chromatography 2014; A 138-147.
Sen I, Zou W, Alvaran J, Nguyen L, Gajek R, She J. Validation of a simple and robust
method for arsenic speciation in human urine using HPLC-ICP-MS. J AOAC International
2015; in press.
Whitehead TP, Crispo-Smith S, Park JS, Petreas MX, Rappaport SM, Metayer C. 2015.
Concentrations of persistent organic pollutants in California women's serum and
residential dust. Environmental Research 2015; 136:57-66.
Zota AR, Linderholm L, Park J-S, Petreas M, Guo T, Privalsky ML, Zoeller RT, Woodruff TJ.
Correction to: A temporal comparison of PBDEs, OH-PBDEs, PCBs, and OH-PCBs in the
serum of second trimester pregnant women recruited from San Francisco General
Hospital, California. Environ. Sci. Technol. 2014; 48. 2512−2513.
Collaboration The Program’s partners and collaborators include community groups, scientists, and other State
of California departments. Collaborating organizations include:
APA Family Support Services
Breast Cancer Fund
Cancer Prevention Institute of California
California Conference of Local Health Officers
DTSC, California’s Green Chemistry Initiative Program
Centers for Disease Control and Prevention
Center for Environmental Research and Children’s Health
CDPH, California Environmental Health Tracking Program
CDPH, Childhood Lead Poisoning Prevention Branch
CDPH, Genetic Disease Screening Program
CDPH, Occupational Health Branch
30
Child Health and Development Studies
Environmental Working Group
Green Science Policy Institute
Kaiser Permanente Division of Research
Lao Seri Association – Laotian Community Services
Natural Resources Defense Counsel
OEHHA, CalEnviroScreen Program
Sierra Streams Institute
Silent Spring Institute
Stanford University
UC Berkeley
UC Davis
UC Irvine
UCLA
UCSF
Vietnamese Family Services
Zero Breast Cancer
Conclusions
Biomonitoring California has been building laboratory capabilities and capacity and other
elements of a robust state biomonitoring program since the Program’s inception. This effort has
begun to generate data that helps assess the effectiveness of current public health and
chemical policy in California. Examples of important findings made possible by Biomonitoring
California’s efforts include:
Pilot and Expanded BEST
Higher levels of arsenic were found in both the Pilot and Expanded BEST populations
compared to the general US population.
Expanded BEST
Arsenic and cadmium (measured in urine) and lead (measured in blood) were detected
in 100% of the samples analyzed; mercury was detected in the blood of 99.7% of the
samples.
Women had higher blood levels of cadmium compared to men, but lower levels of lead.
Asian/Pacific Islanders generally had higher levels of mercury in their blood compared to
other race/ethnic groups.
31
Both Black and Asian/Pacific Islander participants had higher levels of cadmium in urine,
compared to White participants.
Factors potentially contributing to these differences, including lifestyle, diet, and country of
birth, are being investigated.
MAMAS Study
PFC levels measured in archived samples from pregnant women in 2012 are consistent
with levels found in the US population.
Archived serum samples collected through the State prenatal screening program
provide a feasible and efficient means of biomonitoring a limited set of chemicals in a
statewide sample of pregnant women.
Since 2006, the Program’s inception, Biomonitoring California has:
Expanded the biomonitoring capability of the CDPH and DTSC laboratories to measure
over 160 chemicals or their metabolites, across 14 chemical classes.
Dramatically increased capacity for chemical analyses to at least 4000 per year.
Launched five full project collaborations and participated in fourteen laboratory
collaborations.
Launched the first major study using archived samples, which approximates a statewide
representative sample. Although limited to pregnant women who participate in the
State’s prenatal screening program, the MAMAS study offers opportunities to measure
exposures across different regions of the state.
Fulfilled the mandate to return individual biomonitoring results in an understandable
way to participants upon their request.
Launched a new online interactive results database to quickly provide public access to
study results as they become available.
Biomonitoring as Public Health Practice Biomonitoring is an important public health function. It provides a measure of potentially toxic
chemical exposures that may adversely affect the health of the general population; people
living in communities impacted by particular industries/pollutants; and in vulnerable sub-
groups, such as pregnant women, children, and workers.
Biomonitoring California’s analyses provide important data that can help evaluate prevention
activities in California. The Program’s studies also identify highly exposed or vulnerable
populations such as: disadvantaged communities with specific exposure concerns; workers with
potential exposures to chemicals not typically monitored in the workplace; and sensitive
populations like pregnant women and infants.
32
Biomonitoring California has achieved its status as a recognized national leader among state
biomonitoring programs by leveraging state and federal resources and building key
partnerships around the state.
For more information, contact:
Environmental Health Investigations Branch
California Department of Public Health
850 Marina Bay Parkway, Building P-3
Richmond, CA 94804
510-620-3620
This report is available online at biomonitoring.ca.gov/biomonitoring-california-reports.
Appendix A: Program Structure
Biomonitoring California is a complex, multidisciplinary program developed and implemented collaboratively by the California Department
of Public Health (CDPH), Office of Environmental Health Hazard Assessment (OEHHA), and the Department of Toxic Substances Control
(DTSC). This multidisciplinary approach contributes to the success of the program by bringing together expertise in analytical chemistry,
toxicology, and epidemiology. General roles and staff responsibilities for Biomonitoring California are listed below and shown in Figure A1.
Figure A1. Biomonitoring California Departmental Roles and Lead Responsibilities
DTSC Environmental Chemistry
Laboratory
CDPH Environmental Health
Laboratory
CDPH Environmental Health Investigations Branch
OEHHA Reproductive and Cancer
Hazard Assessment Branch
Laboratory analyses of blood samples for persistent chemicals that accumulate in people
Quality assurance and interpretation of laboratory data
Broad screening to identify new chemicals of emerging concern in California
Laboratory analyses of blood samples for metals and urine samples for metals and non-persistent chemicals
Quality assurance and interpretation of laboratory data
Processing and long-term storage of blood and urine samples
Broad screening to identify new non-persistent chemicals of concern in California
Management of analytical results and sample information using Laboratory Information Management System
Overall coordination of program components and partners
Liaison/Principal Investigator on CDC cooperative agreement
Design of statewide and community surveys
Participant recruitment and sample collection
Results communication to participants
Management and analysis of epidemiologic data
Generation of reports to the Legislature
Dissemination of information to the public
Scientific and administrative support of the Scientific Guidance Panel
Evaluation of scientific information for chemical selection, choice of biomarkers, and interpretation of results
Development of chemical fact sheets and protocols for evaluating elevated levels
Outreach to the public, including updates and improvements to the Program website
CDPH is the lead entity, with primary responsibility for: (1) administering Biomonitoring California and
coordinating the technical work of the three departments; (2) overall design of biomonitoring studies,
including both statewide and community surveys, and submitting protocols for human subjects
committee review; (3) participant recruitment, sample collection, and data analysis; (4) receipt,
storage, and analysis of blood and urine samples for metals and chemicals that are not biologically
persistent; (5) quality assurance and interpretation of the laboratory’s test results; (6) communication
of test results to participants and dissemination of information to the public; (7) generation of the
biennial reports; and (8) coordination of the CDC cooperative agreement
OEHHA has primary responsibility for: (1) administering and supporting the SGP; (2) evaluating and
summarizing scientific information for the SGP’s deliberations on chemicals for biomonitoring;
(3) evaluating and summarizing scientific information to interpret and return test results to study
participants; (4) collaborating with CDPH on study design and data analysis; and (5) conducting public
outreach efforts, including through updates and improvements made to the Program’s website:
biomonitoring.ca.gov.
DTSC has primary responsibility for: (1) analysis of blood samples for biologically persistent chemicals,
(2) quality assurance and interpretation of the laboratory’s test results, and (3) exploring
methodologies to identify new and emerging chemicals of concern, including those not yet identified.
Staff members in all three departments collaborate on multiple activities, including program design,
SGP meetings, and data analysis. For example, OEHHA and DTSC staff members contribute to the
program design, for which CDPH is the lead. Similarly, OEHHA convenes the SGP and provides scientific
support, while representatives from DTSC and CDPH provide scientific and other programmatic input
to meeting content, as well as making presentations and responding to questions from the Panel. The
three departments share responsibility for analyzing data collected by Biomonitoring California,
focusing on different scientific issues so that analyses are not duplicative. Selected managers and
senior scientists from the three departments also meet regularly (“Program Leads” meetings) to
coordinate activities. Staff members from the three departments also constitute the Biomonitoring
Interagency Group, which meets twice per month to share information.
Scientific Guidance Panel and Chemical Selection As mandated in SB 1379 (H&SC Sections 105448 and 105449), scientific peer review of Biomonitoring
California is provided by the Scientific Guidance Panel (SGP). The SGP’s rigorous technical input
provides a robust scientific underpinning for Biomonitoring California. OEHHA is responsible for
convening and staffing the Panel and developing scientific documents and other materials to support
the SGP’s deliberations. The Panel consists of nine members appointed by the Governor and the
Legislature. More information on the SGP, including panelists’ biographies, is available online at:
biomonitoring.ca.gov/scientific-guidance-panel.
The Panel met six times during 2014-2015, as required by law. Meeting materials, including agendas,
presentations, scientific documents, other background materials, transcripts, and meeting summaries
35
are also available on the Biomonitoring California website at: biomonitoring.ca.gov/meetings. The
meetings are open to the public and are available via webcast or webinar. The SGP agendas include
ample time for public comment on each item, as well as an open public comment period at the end of
the meeting. Attendees participating in the meeting via the Internet are able to make comments via
email (biomonitoring@oehha.ca.gov).
The SGP performs many functions that are critical to the success of Biomonitoring California. The SGP’s
major role is to review scientific and other materials and provide recommendations on chemicals or
chemical classes that should be included in Biomonitoring California. These are referred to as
“designated chemicals,” which is the entire pool of chemicals that can be considered for inclusion in
Biomonitoring California projects (biomonitoring.ca.gov/chemicals/designated-chemicals). The SGP can
also recommend chemicals as priorities for biomonitoring in the state
(biomonitoring.ca.gov/chemicals/priority-chemicals). The Panel provides feedback on the design and
implementation of Program projects, as well as advice to the laboratories. The SGP gives input on
results return materials for participants, website development, and future Program activities. The
Program also seeks input from the SGP on special topics, and invites outside experts for a richer
discussion. Special topics during 2014-2015 included best practices for biomarker collection, analysis,
and interpretation; approaches for biomonitoring exposures to diesel exhaust; and how best to apply
biomonitoring in efforts to improve the safety of consumer products.
Chemical selection activities in 2014-2015 included consideration by the SGP of various metals and two
chemical classes as designated or priority chemicals, based on criteria related to exposure, health
concerns and feasibility. At the March 2014 SGP meeting, the Panel recommended that chromium be
added to the list of designated chemicals. The Panel also named antimony, beryllium, cobalt,
manganese, molybdenum, thallium, tungsten, and uranium as priority metals for biomonitoring. In
2015, the Panel recommended two classes of chemicals for addition to the list of designated chemicals
and also as priorities for biomonitoring in California: perfluoroalkyl and polyfluoroalkyl substances
(PFASs) and ortho-phthalates.
36
Appendix B: Past Projects and Collaborations
Completed Projects: The Maternal and Infant Environmental Exposure Project (MIEEP), a study of 92 pregnant mothers
and their infants in San Francisco, is complete, with scientific publications in development. MIEEP, also
known as the Chemicals in our Bodies Project, was a collaborative study involving Biomonitoring
California, the UC San Francisco (UCSF) Program on Reproductive Health and the Environment (PRHE),
and the UC Berkeley (UCB) School of Public Health. This study was partially supported by the CDC
cooperative agreement. Biomonitoring California measured environmental chemical exposures in 65
mother-infant pairs and an additional 27 pregnant women. English- and Spanish-speaking pregnant
women were recruited at San Francisco General Hospital (SFGH) in 2010-2011. Urine samples and
questionnaire information were collected in the third trimester of pregnancy, and maternal and
umbilical cord blood samples were collected at delivery. This study was completed in 2013. For more
information on this study, visit biomonitoring.ca.gov/projects/maternal-and-infant-environmental-
exposure-project-mieep.
Among the major accomplishments of MIEEP were the following:
Blood and urine samples from mothers were analyzed for 92 chemicals. Samples from
infant cord blood were tested for 59 chemicals.
Mothers received their results in 2012 and 2013, and were offered suggestions in English
and Spanish on how to reduce exposures.
Infant cord blood was found to contain up to 50 of the 59 chemicals that were
biomonitored. Certain chemicals, including flame retardants, were found at higher levels in
infants than in their mothers.
Results from MIEEP suggest that levels of certain flame retardants banned in California in
2006 (Assembly Bill [AB] 302, Chan, 2003 & AB 2587, Chan, 2004) are declining in the
population, providing support for California’s public health policies.
The Program identified a family with significantly elevated mercury levels in 2011. The
pregnant mother had been using foreign-made skin-lightening creams adulterated with
mercury. This led to a public health alert to medical providers and a subsequent follow-up
study within CDPH to analyze skin-lightening products for mercury and other harmful
contaminants.
Biomonitoring California, along with UCSF and UCB collaborators, will continue to evaluate MIEEP
results for associations between chemical exposures and future health outcomes.
The Firefighter Occupational Exposures (FOX) Study of 101 firefighters in Southern California, is
complete with regard to the original proposed work. The Program is planning to measure OP flame
retardants in archived FOX urine samples. Firefighters are exposed to toxic chemicals in their work
environment more frequently and at higher levels than the general population. The FOX study was
37
conducted in partnership with the UC Irvine’s (UCI) Center for Occupational and Environmental Health
and a Southern California Fire Authority. It was partially supported by the CDC cooperative agreement.
During the course of this study, completed in 2013, Biomonitoring California collected questionnaire
information from 101 firefighters in Southern California, and tested their blood and urine samples. The
protocols and procedures developed in this pilot study will serve as a basis for subsequent
biomonitoring efforts in occupational groups. For more information on the FOX Project, visit
biomonitoring.ca.gov/projects/firefighter-occupational-exposures-fox-project.
Among the study’s major accomplishments were the following:
Blood and urine samples were analyzed for more than 80 distinct chemicals. All participants
who requested their individual results received them in 2012 and 2013. (New results from
OP flame retardant analyses will also be returned to participants who previously requested
their individual results and donated their samples for further study).
Firefighters’ urine levels of BP-3 were significantly higher than the levels reported for the
general population. BP-3, a chemical used as a sunblock in lotions and cosmetics and as an
ultraviolet-light stabilizer in plastic surface coatings, may interfere with the activity of
essential hormones (estrogen and testosterone). A manuscript describing these findings has
been submitted.
Very high levels of polybrominated diphenyl ether (PBDE) flame retardants were measured
in all firefighters, particularly those with classifications consistent with front-line firefighting
activities. Use of personal protection (such as a self-contained breathing apparatus) during
firefighting and salvage operations, and proper cleaning and maintenance of firefighting
gear were associated with lower serum PBDE levels, pointing to the efficacy of health and
safety procedures.
As part of a larger study on contaminants in house dust, dust samples were collected from
several fire stations. Dust was analyzed for some of the same chemicals biomonitored in
firefighters. Levels of PBDEs (and in particular, decaBDE) in fire station dust were much
higher than in dust similarly collected from hundreds of California homes.
Completed Laboratory Collaborations The following six laboratory collaborations have been completed. For more information and
description of these collaborations, visit the links to the Program’s website for the specific projects
below:
1. Center for the Health Assessment of Mothers and Children of Salinas. The Program analyzed
phthalates in urine samples from 5-year-old children living in an agricultural community in the
Salinas Valley (biomonitoring.ca.gov/ projects/center-health-assessment-mothers-and-children-
salinas-chamacos).
2. Cohort of Young Girls’ Nutrition, Environment, and Transitions. The Program analyzed 500
blood samples for metals for a study of teenagers and young girls in the San Francisco Bay Area
38
(biomonitoring.ca.gov/projects/ cohort-young-girls-nutrition-environment-and-transitions-
cygnet).
3. Markers of Autism Risk in Babies – Learning Early Signs. The Program analyzed phthalates in
urine samples from pregnant women who already have an autistic child
(biomonitoring.ca.gov/projects/markers-autism-risk-babies-learning-early-signs-marbles).
4. Pesticide Drift 2 Study. The Program analyzed urine samples from adults and children for
pesticides for a study of individuals living in a rural agricultural community in Tulare County
(biomonitoring.ca.gov/projects/pesticide-drift-2-study).
5. UCSF Studies 1 and 2 of Second-Trimester Pregnant Women. UCSF collected samples from
women seeking care at SFGH in 2008-09 (n = 25 pregnant women) and 2011-12 (n = 36
pregnant women). Biomonitoring California analyzed blood samples for PFCs and other
persistent organic pollutants, including PCBs, OCPs, PBDEs, and hydroxy-PCBs and hydroxy-
PBDEs. For more information on this study, visit biomonitoring.ca.gov/projects/ucsf-studies-
second-trimester-pregnant-women.
6. Women’s Health and the Environment (collaboration with UC Irvine). Women’s Health and the
Environment (WHE) is being conducted by researchers at the UCI Center for Occupational and
Environmental Health. Biomonitoring California analyzed 150 samples for creatinine and PAHs.
The purpose of this collaboration is to examine a possible link between environmental
contaminants and ovarian dysfunction, which is a major cause of infertility. For more
information on this study, visit biomonitoring.ca.gov/projects/womens-health-and-
environment-whe.
top related